Advanced smooth rescue operation

What is claimed is: 1. A method of operating an elevator system, the method comprising: detecting, using a controller, when an external power source is unavailable; controlling, using the controller, a plurality of components of the elevator system, wherein controlling comprises operating at least one of an elevator car, a drive unit, an inverter and a brake; detecting, using the controller, an original direction of travel of the elevator car; detecting, using the controller, a mode of the elevator car, wherein the mode includes at least one of a motoring mode, a near balance mode, and a regenerative mode; determining, using the controller, a target floor; and adjusting, using the controller, a velocity of the elevator car to reach the target floor in response to the mode detected; allowing, using the controller, the velocity of the elevator car to decrease to about zero velocity, when the near balance mode is detected; maintaining, using the controller, the about zero velocity for a selected duration of time; increasing, using the controller, the velocity of the elevator car in the original direction of travel until it reaches an automatic rescue operation velocity; maintaining, using the controller, the automatic rescue operation velocity for a second selected duration of time; and decreasing, using the controller, the velocity of the elevator car as the elevator car approaches the target floor; wherein secondary power is provided to the brake, elevator doors, and a positional reference system in the controller; wherein secondary power is not provided to a drive unit to propel the elevator. 2. A method of operating an elevator system, the method comprising: detecting, using a controller, when an external power source is unavailable; controlling, using the controller, a plurality of components of the elevator system, wherein controlling comprises operating at least one of an elevator car, a drive unit, an inverter and a brake; detecting, using the controller, an original direction of travel of the elevator car; detecting, using the controller, a mode of the elevator car, wherein the mode includes at least one of a motoring mode, a near balance mode, and a regenerative mode; determining, using the controller, a target floor; adjusting, using the controller, a velocity of the elevator car to reach the target floor in response to the mode detected; allowing, using the controller, the velocity of the elevator car to decrease to about zero velocity, when the motoring mode is detected; allowing, using the controller, the velocity of the elevator car to increase in a direction opposite the original direction of travel to a selected creep velocity; deactivating, using the controller, the inverter when the selected creep velocity is less than a selected velocity in the direction opposite the original direction of travel; increasing, using the controller, the velocity of elevator car in the direction opposite the original direction of travel to a selected alternate creep velocity; maintaining, using the controller, the selected alternate creep velocity for a selected duration of time; decreasing, using the controller, the velocity of the elevator car in the direction opposite the original direction of travel, when the selected duration of time ends; adjusting, using the controller, the velocity of the elevator car as the elevator car approaches the target floor; and applying, using the controller, the brake when the elevator car is at the target floor. 3. An apparatus for operating an elevator system, the apparatus comprising: an elevator car; a drive unit; an inverter; a brake; a controller to control a plurality of components of the elevator system, wherein controlling comprises operating at least one of the elevator car, the drive unit, the inverter, and the brake, wherein the controller performs operations comprising: detecting when an external power source is unavailable, detecting an original direction of travel of the elevator car, detecting a mode of the elevator car, wherein the mode includes at least one of a motoring mode, a near balance mode, and a regenerative mode, determining a target floor, and adjusting a velocity of the elevator car to reach the target floor in response to the mode detected; allowing, using the controller, the velocity of the elevator car to decrease to about zero velocity, when the near balance mode is detected; maintaining, using the controller, the about zero velocity for a selected duration of time; increasing, using the controller, the velocity of the elevator car in the original direction of travel until it reaches an automatic rescue operation velocity; maintaining, using the controller, the automatic rescue operation velocity for a second selected duration of time; and decreasing, using the controller, the velocity of the elevator car as the elevator car approaches the target floor wherein secondary power is provided to the brake, elevator doors, and a positional reference system in the controller; wherein secondary power is not provided to a drive unit to propel the elevator. 4. An apparatus for operating an elevator system, the apparatus comprising: an elevator car; a drive unit; an inverter; a brake: a controller to control a plurality of components of the elevator system, wherein controlling comprises operating at least one of the elevator car, the drive unit, the inverter, and the brake; wherein the controller performs operations comprising: detecting when an external power source is unavailable; detecting an original direction of travel of the elevator car; detecting a mode of the elevator car, wherein the mode includes at least one of a motoring mode, a near balance mode, and a regenerative mode; determining a target floor; adjusting a velocity of the elevator car to reach the target floor in response to the mode detected; allowing the velocity of the elevator car to decrease to about zero velocity, when the motoring mode is detected; allowing the velocity of the elevator car to increase in a direction opposite the original direction of travel to a selected creep velocity; deactivating the inverter when the selected creep velocity is less than a selected velocity in the direction opposite the original direction of travel; increasing the velocity of elevator car in the direction opposite the original direction of travel to a selected alternate creep velocity; maintaining the selected alternate creep velocity for a selected duration of time; decreasing the velocity of the elevator car in the direction opposite the original direction of travel, when the selected duration of time ends; adjusting the velocity of the elevator car as the elevator car approaches the target floor; and applying the brake when the elevator car is at the target floor.